Probing the cosmic-ray content of galaxy clusters by stacking Fermi-LAT count maps

TL;DR

This study uses stacked Fermi-LAT gamma-ray data to search for cosmic-ray induced emission in galaxy clusters, setting upper limits on cosmic-ray content and suggesting less efficient cosmic-ray injection at shocks than previously thought.

Contribution

It provides the first comprehensive gamma-ray stacking analysis of galaxy clusters, constraining cosmic-ray content and comparing cool-core and non-cool-core populations.

Findings

No significant gamma-ray signal detected from the stacked clusters.

Upper limits on gamma-ray flux imply a maximum of 4.6% cosmic-ray to thermal energy ratio.

Results are consistent with simulations indicating less efficient cosmic-ray injection.

Abstract

Observations in radio have shown that galaxy clusters are giant reservoirs of cosmic rays (CR). Although a gamma- ray signal from the cluster volume is expected to arise through interactions of CR protons with the ambient plasma, a confirming observation is still missing. We search for a cumulative gamma-ray emission in direction of galaxy clusters by analysing a collection of stacked Fermi-LAT count maps. Additionally, we investigate possible systematic differences in the emission between cool-core and non-cool core cluster populations. Making use of a sample of 53 clusters selected from the HIFLUGCS catalog, we do not detect a significant signal from the stacked sample. The upper limit on the average flux per cluster derived for the total stacked sample is at the level of a few 1e-11 ph cm-2 s-1 at 95% confidence level in the 1-300 GeV band, assuming power-law spectra with photon indices 2.0, 2.4, 2.8 and 3.2. Separate stacking of the cool core and non-cool core clusters in the sample lead to similar values of around 5e-11 ph cm-2 s-1 and 2e-11 ph cm-2 s-1, respectively. Under the assumption that decaying pi0, produced in collisions between CRs and the ambient thermal gas, are responsible for the gamma-ray emission, we set upper limits on the average CR content in galaxy clusters. For the entire cluster population, our upper limit on the gamma-ray flux translates into an upper limit on the average CR-to-thermal energy ratio of 4.6% for a photon index of 2.4, although it is possible for individual systems to exceed this limit. Our 95% upper limits are at the level expected from numerical simulations, which likely suggests that the injection of CR at cosmological shocks is less efficient than previously assumed.